Method, apparatus and computer-readable media utilizing positional information to derive AGC output parameters

ABSTRACT

Method and apparatus for automatic gain control utilizing sound source position information in a shared space having a plurality of microphones and a plurality of sound sources. Sound signals are received from the microphones. One or more processors locate position information corresponding to each of the sound sources. The processor(s) determine the distance to each of the sound sources from each of the microphones. The processor(s) define a predetermined gain weight adjustment for each of the microphones. The processor(s) apply the defined weight adjustments to the microphones to achieve a consistent volume of the desired plurality of sound sources. The processor(s) maintain a consistent ambient sound level regardless of the position of the sound sources and the applied gain weight adjustments. The processor(s) output a summed signal of the sound sources at a consistent volume with a constant ambient sound level across the plurality of sound source positions.

This application is a divisional application of U.S. patent applicationSer. No. 16/434,725, filed Jun. 7, 2019, which is a continuation of U.S.patent application Ser. No. 15/603,986, filed May 24, 2017, now U.S.Pat. No. 10,387,108, issued Aug. 20, 2019, which claims priority to U.S.Provisional Patent Application No. 62/393,461, filed Sep. 12, 2016, theentire contents of all incorporated herein by reference.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention generally relates to utilizing positional 3Dspatial sound power information for the purpose of deterministicautomatic gain control to adjust a dynamically configured microphonearray in at least near real-time for multi-user conference situationsfor optimum audio signal and ambient sound level performance.

2. Description of Related Art

Obtaining high quality audio at both ends of a conference call isdifficult to manage due to, but not limited to, variable roomdimensions, dynamic seating plans, roaming participants, unknownmicrophone locations, different microphone sensitivities, known steadystate and unknown dynamic noise, and variable desired sound sourcelevels. This results in audio sound sources having wide dynamic rangewithin the ambient sound environment. Because of the complex needs andrequirements, solving the problems has proven difficult and insufficientwithin the current art.

In the currently known art there have been various approaches to solvingthe complex issue of managing wide dynamic range audio signals withacceptable ambient sound level performance from multi-location basedsound and signal sources. Typically, this is accomplished usingheuristic-based automatic gain control techniques to enhance audioconferencing system performance in a multi-user room. Automatic gaincontrol is used to bring the desired signal, which in this case may bebut is not limited to a speaking participant in the room, to within anacceptable dynamic range to be transmitted to remote participantsthrough third party telephone, network and/or teleconference softwaresuch as Microsoft Skype, for example. If automatic gain control was notimplemented the conversations would be hard to hear with the soundvolume levels swinging from very low level to very loud levels. Thecommunication system may not be able to manage the signal properly, withtoo little signal strength to be heard clearly or too much signalstrength, which would overdrive the system resulting in clipping of thesignal and adding significant distortion. Either scenario would not beacceptable in an audio conference situation. If the signal is within asufficient range to propagate through the system, the resulting dynamicrange swings would require the remote participants to continually adjusttheir volume control to compensate for the widely variable leveldifferences that would be present for each individual speakingparticipant. An unwanted byproduct of typical automatic gain controlcircuits is the ambient sound levels also tracking in proportion tovolume changes by the remote participant.

Automatic gain control is typically applied as a post-processingfunction within a variable gain amplifier or after the analog digitalconverter in a digital signal processor isolated from the microphoneprocessing logic. The automatic gain control does not know a keyparameter such as the position of the sound source 103, which means theautomatic gain control will need to operate on heuristic principals,assumptions, and configuration limits. This is problematic because theautomatic gain control solutions have to work on heuristic principalsbecause the actual location of the sound and ambient sound sources arenot known, which means the performance of the automatic gain control isnot deterministic. This results in serious shortcomings by not beingable to adapt to and provide consistent performance and acceptable enduser experiences. Automatic gain control systems which need to deal withlarge dynamic range signals end up having to adjust the gain of thesystem, which can show up as sharp unexpected changes in backgroundambient sound levels. The automatic gain control will appear to hunt forthe right gain setting so there can be a warbling and inconsistent soundlevels making it difficult to understand the person speaking. Theautomatic gain control is trying to normalize to preset parameters thatmay or may not be suitable to the actual situation, as designers cannotanticipate all scenarios and contingencies that an automatic gaincontrol function must handle. Third party conference and phone softwaresuch as but not limited to Microsoft Skype, for example, havespecifications that need to be met to guarantee compatibility,certifications, and consistent performance. Automatic gain controls inthe current art do not know the distance and the actual sound levels ofthe sound source 104 (e.g., Participant 2 in FIG. 1 ) that they aretrying to manage, resulting in inconsistent sound volume when switchingsources and fluctuating ambient sound level performance. This makes forsolutions that are not deterministic and do not provide a high level ofaudio performance and user experience.

Thus, the current art is not able to provide consistent performance inregards to a natural user experience regarding desired source signallevel control and consistent ambient sound level performance.

An approach in the prior art is to utilize various methods to determinesource location targeting parameters to determine Automatic Gain Control(AGC) settings. However, the systems in the prior art address a gainadjustment method that does not adequately manage the ambient noiselevels to a consistent level, regardless of targeted AGC parameters,which is problematic for maintaining a natural audio listeningexperience with consistent ambient noise levels for conferenceparticipants.

U.S. Pat. No. 4,499,578 discloses multiport digital conferencearrangements wherein speech samples of selected speakers are summed fordistribution to the conferees. The embodiment controls the level ofspeech represented by information samples to be included in an outputsample for distribution to the ports, and equalizes the speech levelbetween speakers to reduce speech level contrast heard by the conferees.In addition, a speech detector for each port andmicroprocessor-controlled switching hardware also adjust the signallevel represented by samples received on the ports to effect speakerselection. Furthermore, gain coefficients for a port may beincrementally adjusted during a predetermined period of time to avoidnoticeable signal level changes when implementing speaker selection.

U.S. Pat. No. 7,130,705 discloses a system and method for automaticallyadjusting the gain of an audio system as a speaker's head moves relativeto a microphone includes using a video of the speaker to determine anorientation of the speaker's head relative to the microphone and, hence,a gain adjust signal. The gain adjust signal is then applied to theaudio system that is associated with the microphone to dynamically andcontinuously adjust the gain the audio system.

U.S. Pat. No. 8,185,387 describes methods and systems for adjustingaudio gain levels for multi-talker audio. In one example, an audiosystem monitors an audio stream for the presence of a new talker. Uponidentifying a new talker, the system determines whether the new talkeris a first-time talker. For a first-time talker, the system executes afast-attack/decay automatic gain control (AGC) algorithm to quicklydetermine a gain value for the first-time talker. The systemadditionally executes standard AGC techniques to refine the gain for thefirst-time talker while the first-time talker continues speaking. When asteady state within a decibel threshold is attained using standard AGCfor the first-time talker, the system stores the steady state gain forthe first-time talker to storage. Upon identifying apreviously-identified talker, the system retrieves from storage thesteady state gain for the talker and applies the steady state gain tothe audio stream.

U.S. Pat. No. 5,477,270 describes using a camcorder which includes acamera section receiving a subject image subject through a zoom lens,converting the subject image to a video signal, and generating acorresponding wide/tele signal representing the position of the zoomlens, an audio processing part including a plurality of microphonesreceiving input sounds from the subject and converting the input soundsinto a recordable audio signal, and a recorder/reproducer which recordsand reproduces the video signal and the recordable audio signal ontovideo tape. The audio processing part includes a plurality of analogelements. The audio processing part continuously amplifies the inputaudio signal using the analog elements in response to the wide/telesignal and outputs the recordable audio signal which corresponds toperceived distance from the camcorder to the subject. The analogelements may be transistors, wherein the dynamic resistance of eachtransistor is continuously varied responsive to the wide/tele signal.

U.S. Patent Application No. 2008/0085014 describes a gain adjustingsystem for adjusting a gain of a sound signal in an audio system, andincludes a first detecting unit for capturing images of one or morefaces of users and determining the number of faces and the size of thefaces present in the images; a controller for receiving face data fromthe first detecting unit for comparing the sizes of faces insubsequently captured images with an initial face size and accordinglydeciding and outputting a first decision signal; and a gain regulatorcoupled to the controller for adjusting the gain level of the soundsignal according to the first decision signal.

U.S. Pat. No. 7,848,531 describes a method were the overall loudness ofan audio track is calculated by combining a number of weighted loudnessmeasures for segments of the audio track. The weight applied to eachindividual loudness measure is a function of the loudness measure. Bycomparing the original overall loudness measure to a desired overallloudness measure, a gain can be determined that will adjust the loudnesslevel to the desired value. Also disclosed is a dynamic compressionmethod that analyzes the dynamic characteristics of an audio track anddetermines appropriate compressor parameters. Additionally, the loudnessof a post-compressor audio track can be estimated for any givencompressor parameters, thus permitting post-compression loudnessmatching to be done even if the compression is performed in real-time.

SUMMARY OF THE INVENTION

An object of the present embodiments is to allow for a consistent volumeof the sound source 104 no matter where it is located in the range ofthe system, while keeping the background ambient sounds at a constantlevel.

In one embodiment of the present invention, the dynamically measuredposition of the sound source (from a position processor or like process)is used.

Utilizing the positional coordinate information, a system having aChannel Audio Processor can calculate and control the individualmicrophone gain and selection of the microphone array utilizing derivedrepeatable gain values, based on known path loss calculations, toovercome the limitations of a heuristic post processing automatic gaincontrol system. One advantage of this embodiment is that it operatesdeterministically and can use known sound pressure level propagationformulas over distance, to account for signal path loss situations on anindividual basis, deriving the appropriate required gain adjustment foreach sound source relative to the microphone array. Because the gain ispreferably managed on an individual sound source location basis, thedisadvantages of a broad-based automatic gain control circuit of thewhole signal chain is not incurred, resulting in a consistent volumewith stable ambient signal performance held to unity gain values,without the typical up and down normalizing and hunting that is typicalof automatic gain control functions.

Typical solutions in the current art base the amplification orcompression solely on the audio signal strength. This simple approach issubject to extreme ambient sound fluctuations. As the source signal goesdown in level, the automatic gain control will increase the gain tocompensate. This has the effect of bringing the relative ambient soundup as well. A natural extension of this is when there is no sourcesignal present, the automatic gain control goes to max gain to bring upa signal that is not present, which greatly increases the ambient soundin the system. This situation is avoided within the presently preferredembodiments as there is preferably no controlling the gain compensationbased on sound source level, but instead on position and path loss; ifthere is no sound source, the preferred embodiments will notartificially try and raise the ambient sound level. According to thepreferred embodiments, there needs to be a signal present and located toderive the gain values.

The preferred embodiments comprise both algorithms and hardwareaccelerators to implement the structures and functions described herein.

According to a first aspect of the present invention, a method ofautomatic gain control utilizing sound source position information in ashared space having a plurality of microphones and a plurality of soundsources receives sound signals from the plurality of microphones. One ormore processors is/are used to locate position information correspondingto each of the plurality of sound sources in the shared space. The oneor more processors is/are used to determine the distance to each of theplurality of sound sources from each of the plurality of the microphonesin the shared space, based on the position information. The one or moreprocessors is/are also used to define a predetermined gain weightadjustment for each of the plurality of microphones, based on thedistance information. The one or more processors is/are used to applythe defined plurality of gain weight adjustments to the plurality ofmicrophones in order to achieve a consistent volume of the desiredplurality of sound sources in the shared space. The one or moreprocessors is/are used to maintain a consistent ambient sound levelregardless of the position of the plurality of sound sources and theapplied gain weight adjustments to the plurality of microphones, basedon received signals from the plurality of microphones. And the one ormore processors is/are used to output a summed signal of the pluralityof sound sources at a consistent volume with a constant ambient soundlevel across the plurality of sound source positions in the sharedspace.

According to a second aspect of the present invention, apparatusbalancing audio from an audio source in a multi-microphone array has atleast one position processor receiving outputs from each of themicrophones in the multi-microphone array, the outputs corresponding toa position of the audio source with respect to the multi-microphonearray. At least one gain weight processor is coupled to the at least oneposition processor, and is configured to differently-weight signals fromat least two of the microphones of the multi-microphone array, based onat least one output from the at least one position processor, in orderto provide (i) substantially stable background sound level and (ii)substantially consistent sound level of the audio source.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic illustration of the Gain Mapping Zones,according to the preferred embodiments.

FIG. 2 is a diagrammatic illustration of Automatic Gain Control ChannelProcessor, according to the preferred embodiments.

FIG. 3 is a diagrammatic example of the Automatic Gain Controlcalculation with a participant outside of the Configurable ThresholdDistance.

FIG. 4 is a diagrammatic example of the Automatic Gain Controlcalculation with a participant inside of the Configurable ThresholdDistance.

FIG. 5 is a diagrammatic example of the Automatic Gain Controlcalculation with a participant inside of the Minimum Threshold Distance.

FIGS. 6 a and 6 b are respectively a hardware diagram and a softwareflowchart depicting processing gain.

DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED Exemplary Embodiments

The present invention is directed to apparatus and methods that enablegroups of people (and other sound sources, for example, recordings,broadcast music, Internet sound, etc.), known as “participants”, to jointogether over a network, such as the Internet or similar electronicchannel(s), in a remotely−distributed real-time fashion employingpersonal computers, network workstations, and/or other similarlyconnected appliances, often without face-to-face contact, to engage ineffective audio conference meetings that utilize large multi-user rooms(spaces) with distributed participants.

Advantageously, embodiments of the present apparatus and methods providean ability to provide remote participants an end user experience havingall sound sources at a consistent volume level, regardless of theirlocation with respect to the microphone array, while maintainingconsistent ambient sound and ambient sound source levels at all times.

A notable challenge to picking up sound clearly in a room, cabin, orconfined space is the dynamic nature of the sound sources, resulting ina wide range of sound pressure levels, while maintaining realistic andconsistent ambient sound levels for the remote participant(s).

A “device” in this specification may include, but is not limited to, oneor more of, or any combination of processing device(s) such as, a cellphone, a Personal Digital Assistant, a smart watch or other body-bornedevice (e.g., glasses, pendants, rings, etc.), a personal computer, alaptop, a pad, a cloud-access device, a white board, and/or any devicecapable of sending/receiving messages to/from a local area network or awide area network (e.g., the Internet), such as devices embedded incars, trucks, aircraft, household appliances (refrigerators, stoves,thermostats, lights, electrical control circuits, the Internet ofThings, etc.).

An “engine” is preferably a program that performs a core function forother programs. An engine can be a central or focal program in anoperating system, subsystem, or application program that coordinates theoverall operation of other programs. It is also used to describe aspecial-purpose program containing an algorithm that can sometimes bechanged. The best known usage is the term search engine which uses analgorithm to search an index of topics given a search argument. Anengine is preferably designed so that its approach to searching anindex, for example, can be changed to reflect new rules for finding andprioritizing matches in the index. In artificial intelligence, foranother example, the program that uses rules of logic to derive outputfrom a knowledge base is called an inference engine.

As used herein, a “server” may comprise one or more processors, one ormore Random Access Memories (RAM), one or more Read Only Memories (ROM),one or more user interfaces, such as display(s), keyboard(s),mouse/mice, etc. A server is preferably apparatus that providesfunctionality for other computer programs or devices, called “clients.”This architecture is called the client-server model, and a singleoverall computation is typically distributed across multiple processesor devices. Servers can provide various functionalities, often called“services”, such as sharing data or resources among multiple clients, orperforming computation for a client. A single server can serve multipleclients, and a single client can use multiple servers. A client processmay run on the same device or may connect over a network to a server ona different device. Typical servers are database servers, file servers,mail servers, print servers, web servers, game servers, applicationservers, and chat servers. The servers discussed in this specificationmay include one or more of the above, sharing functionality asappropriate. Client-server systems are most frequently implemented by(and often identified with) the request-response model: a client sends arequest to the server, which performs some action and sends a responseback to the client, typically with a result or acknowledgement.Designating a computer as “server-class hardware” implies that it isspecialized for running servers on it. This often implies that it ismore powerful and reliable than standard personal computers, butalternatively, large computing clusters may be composed of manyrelatively simple, replaceable server components.

The servers and devices in this specification typically use the one ormore processors to run one or more stored “computer programs” and/ornon-transitory “computer-readable media” to cause the device and/orserver(s) to perform the functions recited herein. The media may includeCompact Discs, DVDs, ROM, RAM, solid-state memory, or any other storagedevice capable of storing the one or more computer programs.

FIG. 1 illustrates a room 110 with a microphone array 111, whichcomprises a plurality of microphones 112. This diagram illustrates thevarious configuration zones that are available for the microphone array111.

For the purpose of this embodiment, the microphone array 111 ispositioned against a wall; however the position of the microphone array111 can be against any wall in the room 110. There are notionally threeparticipants illustrated in the room, Participant 1 107, Participant 2104 and Participant 3 102. Participant(s) and sound source(s) can andwill be used interchangeably and in this context mean substantially thesame thing. Each Participant illustrates, but is not limited to, anexample of the variability of position 103 within a room 110. Theembodiments are designed to adjust for and accommodate such positions(stationary and/or moving). For example, each Participant may be moving,and thus have varying location coordinates in the X, Y, and Zdirections. Also illustrated is an ambient sound 101, which may bepresent and propagated throughout the room, such that it is relativelyconstant for each participant 107, 104, 102 locations. For example, theroom ambient noise may be one or more of HVAC noise, TV noise, outsidenoise, etc.

Also illustrated in FIG. 1 is a Minimum Threshold Distance (MTD) 109 anda Configurable Threshold Distance (CTD) 108. The area inside the CTD 108is the microphone array 111 configuration zone. In that zone, utilizingthe specific distance P2 d(m) (e.g., distance in metric) 105 of theparticipant 2 104, the array will be configured for individual gain andmicrophone selection to stabilize the array 111 volume output andambient sound level 101 relative to the Participant 2 location 104.Within the CTD 108 there is preferably enough positional 103 resolutionof the system to utilize distance path loss 105 to tune the array 111for individual microphone 112 gain-weighted measurements. Within thezone of the CTD 108 and the MTD 109, the microphone array 111 isdynamically configured to utilize between 1-12 of the microphones 112,based on the position 103 of the sound source 104.

For participants 102 outside the CTD 108, preferably all microphones 111are used. As the sound source 104 gets further from the CTD 108, itsperceived volume will drop off. This is the preferred behavior as it maybe undesirable to pick up people far away and have them sound as if theyare in the room.

For participants 104 in the zone between the MTD 109 and the CTD 108,the system will preferably pick the n+1 microphones 112 which areclosest to the location 103 of the sound source 104 to act as themicrophone array (e.g., one of them will only be fractionally on) andthe remainder are preferably turned off.

When a participant 107 is within the MTD 109, the system will preferablyselect a pair of microphones 112 in the array 111, so that the ambientsound level 101 can be maintained with one microphone 112 fully on andone fractionally on, e.g., 5%, 10%, 15%, 20%, 25%, 30%, 35%, 40%, 45%,50%, or any value between 1% and 99%. When the participant 107 getswithin the MTD of the closest microphone, the array will preferably nolonger use that microphone. Instead, the system preferably uses one ormore other microphones further away, that are outside theclosest-microphone MTD in order to control the gain of the sound source104. If the microphones are spaced close enough, there will usuallyexist a microphone in the range where n=1. The maximum microphonespacing allowed is preferably (sqrt(2)−1)*MTD.

Beyond the CTD 108, all 12 microphones (or however many microphones arein the array, e.g., any number between 2 and 100; and the “array” may bea one−dimensional array, a two−dimensional matrix array, or athree−dimensional linear or matrix array having certain microphones atdifferent distances from a Z-axis baseline) 112 of the microphone array111 are preferably sequentially enabled as the positional information103 (obtained from the system) becomes too granular and the bestperformance is realized with all 12 microphones in operation. Both theMTD 109 and the CTD 108 are preferably system-configurable parametersthat are set based on the microphone array 111 parameters and the room110 parameters.

FIG. 2 illustrates the system Position Processor 202 and the automaticgain control Channel Processor 201. Although one Channel Processor 201is shown the embodiments, the implementation may utilize a plurality ofchannel processors 201, resulting in multiple audio channels 210 withindividual microphone array 111 gain control capabilities running inparallel.

This allows for unique microphone array tunings for each sound source104 position 107, 104, 102 with known positional coordinates 103. EachChannel Audio Processor preferably includes at least one Gain WeightProcessor 203 and at least one Delay Processor 204. Each “processor” maycomprise one or more processor chips or boards, which may be co-locatedor remotely located with respect to each other. The presently preferredembodiments contemplate at least one Field Programmable Gate Array(FPGA) as the Position Processor 202, and a Digital Signal Processor(DSP) as the Gain Weight Processor 203. However, these processors maycomprise one or more circuits and/or applications installed in one ormore personal computers and/or Application Specific Integrated Circuits(ASICs). These processors may run program code permanently storedtherein or stored in removable media. The program code preferablycomprises one or more modules and/or engines to perform the variousfunctions described herein.

FIG. 2 shows a microphone array 112 (comprising a plurality ofmicrophones 111) which is connected to a Position Processor 202. Oneembodiment may comprise the processor described and depicted in U.S.Provisional Appln. No. 62/343,512, filed May 31, 2016, BUBBLE PROCESSOR,the entire contents of which are incorporated herein by reference. Seealso U.S. Provisional Appln. No. 62/162,091, filed May 15, 2015, ASYSTEM FOR PROCESSING AUDIO; U.S. Provisional Appln. No. 62/345,208,filed Jun. 3, 2016, VIRTUAL POSITIONING IN A SOUND SPACE, the entirecontents of both of which are incorporated herein by reference).

The Position Processor 202 utilizing the Microphone Array signals 216preferably determines the substantially exact positional location 103(X,Y,Z) coordinates of the sound source 104 with the highest processinggain. This is the sound source 104 that the microphone array will focuson. The Position Processor 202 preferably runs independent of theChannel Processor 201. The Position Processor 202 preferablycommunicates the positional information 209 to the Channel Processor201, which comprises the Delay Processor 204 and the Gain WeightProcessor 203. The Channel Processor preferably runs at the requiredsample rates (e.g., 24 kHz) to support the desired frequency responsespecifications, meaning the sample rates are not limited by theinvention implementation in the embodiments.

The sound pressure level (SPL) of the sound wave follows a verypredictable loss pattern where the SPL is inversely proportional to thedistance P2 d(m) 105 from the source Participant 2 104 to the microphonearray 111. Since the positional information 209 derived from thePosition Processor 202 is known, the distance P2 d(m) 105 can becalculated, and the Gain Weight Processor calculates the gain required,on a per microphone 112 basis, based on the distance 105 to eachmicrophone 112 of the microphone array 111. Once the Gain Weightparameters 213 Alpha (α=the multiplication factor to be applied to eachof the fully-on microphone signals. F α=the multiplication factor to beapplied to the fractionally-on microphone signal (f is preferably avalue between 0 and 1)); and the f*Alpha parameters have beencalculated, they are multiplied 205 with the individual Microphone 112signals 212, resulting in weighted output parameters 215 that have beengain-compensated based on the actual distance 105 from the microphone112 in the microphone array 111. This process accomplishes the specificautomatic gain control function, which adjusts the microphone levels 215that are preferably sent to the delay elements.

The delays in the microphone array 111 are calculated using thepositional information 209 from the Position Processor 202 in the DelayProcessor 204. The Delay Processor 204 preferably calculates theindividual path loss delays d(m) in milliseconds for each microphone 112relative to the sound source 104 location 103. It then preferably addsthe extra DELAY into each microphone path of D−d(m) so that the overallDELAY between the sound source 104 and the summer 206 through all themicrophone paths is preferably a constant D. The value constant D wouldtypically be the delay through the longest path between a microphone 112and a position monitored by the position processor 202, measured inmilliseconds. For example if the longest distance between the 12antennas and the 8192 points monitored by the position processor is 10m, then then the value of D would be that distance converted into adelay, about 30 ms. The result is that signals from all microphones 112are aligned in the time domain, allowing for maximum natural gain of alldirect signal path signals to the microphone array 111. All of theoutput signals 216 are preferably summed at the Summer 206 and outputfor further system processing. The resulting delays are applied to allof the microphones whether they will be used by the Gain WeightProcessor 203 or not.

To provide gain control of the desired signal without affecting theambient sound level is preferably accomplished through the followingmethods. This is accomplished by controlling the processing gain of themicrophone array 112. Processing gain is how much the array 112 booststhe desired signal source relative to the undesired signal sources. Asillustrated with a linear microphone array 111, the processing gain isroughly the square root of the number of microphones in use (√{squareroot over (12)}=3.46 if we use all 12 microphones). When it is desiredto reduce the volume of the focused signal without affecting ambientlevels 101, the microphones 112 in the array 111 are turned off toreduce the gain and provide the proper scaling constants to keep theambient sounds 101 at the same level. For example, if half themicrophones are turned off, the gain drops to √{square root over(6)}=2.45, or a 3 dB drop from 12 microphones.

In this embodiment, the maximum gain that can be achieved with all 12microphones is 3.46, and the minimum gain (when reduced to a singlemicrophone) is 1. This gives a 10.8 dB gain range. The CTD 108 ispreferably where to set the desired signal levels with all 12microphones 112 on. Below the CTD 108, the microphones in the array 111are preferably individually turned off to maintain a consistent soundlevel. Beyond the CTD 108, the system typically cannot produce moregain, so the sound level will drop off with the inverse distance law.

To optimize the implementation embodiments, it is not preferred to justswitch microphones 112 in and out, since this may cause undesirablejumps in the sound volume. To make the adjustments continuous, it ispreferable to assign some number of microphones 112 to be fully turnedon and one microphone 112 to be partially turned on. The partiallyturned-on microphone 112 allows a smooth transition from one set ofmicrophone(s) to another, and to implement any arbitrary gain within thelimits.

Calculation of microphone gain parameters. It is preferred to determinea specific gain, G_(focus), for the focused signal while keeping thebackground gain, G_(bg), at unity. To do this, it is preferred to turn nmicrophones 112 on fully and have one microphone 112 on fractionallywith a constant f that is somewhere between 0 and 1. Each microphonesignal is preferably weighted by the common constant α. Given theassumptions that the background signals are orthogonal so they add bypower when combined, and that the levels of the signals arriving at eachmicrophone 112 are equal, the rms gain of n signal with a gain of α andone signal with a gain of fα is:G _(bg)=α√{square root over (n+f ²)}  (1)Setting G_(bg) to unity to keep it constant gives:α=1/√{square root over (n+f ²)}  (2)The array 111 is designed to combine the focused source coherently sothe signals from this source add by amplitude. The coherent gain of thefocused source is:G _(focus)=a(n+f)  (3)Substituting (2) into (3) gives:

$\begin{matrix}{G_{focus} = \frac{n + f}{\sqrt{n + f^{2}}}} & (4)\end{matrix}$For a given G_(focus), first assume that f=0 and find the largestinteger n that give a result less than or equal to G_(focus)n=floor (G _(focus) ²)  (5)Then solve for fG _(focus)√{square root over (n+f ²)}n+f  (6)G _(focus) ²(n+f ²)=n ²+2nf+f ²  (7)(G _(focus) ²−1)f ²−2nf+(G _(focus) ² n−n ²)=0  (8)Equation (8) can be solved for f using the standard quadratic equationand picking the solution where 0≤f<1. Then compute a from equation (2).

The logic flow is as follows:

-   Gm is the maximum gain of the array (Gm=sqrt(number of microphones))-   Dc is the configurable threshold distance 108-   Dm is the minimum threshold distance 109 where the array gain is    unity (Dm=Dc/Gm)-   Use sound source 104 location (x,y) 103 and the known microphone 112    locations to determine the distance to the closest microphone (d)    117-   If d>Dc-   Set n=number of microphones-   Set f=0-   calculate the weight factor, alpha, and apply it to all microphones.-   else if (Dm<d<Dc)-   calculate the desired processing gain to compensate for path loss    G=Gm*d/Dc-   calculate number of full gain microphones, n, required to achieve    desired gain-   calculate fractional amount for the additional microphone, f-   calculate the weight factor, alpha-   calculate the gain for each individual microphone (zero for unused    microphone, alpha for full on, and f*alpha for fractionally on)-   choose the n+1 closest microphone(s) to the sound source 104 to use    in the array (the furthest is the fractional microphone)-   else if d<minimum threshold distance-   recalculate d for the closest microphone that is greater than Dm    from the sound source 104, this will be on full-   (if microphones are placed close enough together then n=1    automatically)-   choose the next furthest microphone to act as the fractional    microphone-   calculate the fractional amount, f-   calculate the weight factor alpha-   calculate the gain for each individual microphone (zero for unused    microphone, alpha for full on, and f*alpha for fractionally on)

FIG. 3 illustrates the microphone arrangement 303 and the gain weightvalues α when a participant 301 is located outside of the CTD 108. TheFigure shows a preferred structure (one or more circuits) comprising themicrophone arrangement 303, Gain Weight Multipliers 205, and the Summer206. The MTD 109 for this embodiment has been set to 57.7 cm, and theCTD has been set to 200 cm. The position of the participant 301 has beendetermined by the Position Processor 202, and the Gain Weight Processor203 has determined the distance 302 to be 260 cm. This positions theparticipant 301 outside of the CTD 108. Based on the embodimentcalculations per the above discussion, the calculated Gain Value used toset the Channel Processor AGC 201 to is 3.64 in this embodiment. Allmicrophones 303 are enabled, n=12, and the per microphone α gain valueis 0.289. Since all microphones 303 are fully enabled there is nofractional gain value and f=0.

FIG. 4 illustrates the microphone arrangement 403 and gain weight valuesα when a participant 401 is located inside of the CTD 108 but not withinthe MTD 109. The Figure shows the circuit comprising the microphonearrangement 403, Gain Weight Multipliers 205, and the Summer 206. TheMTD 109 has been set to 57.7 cm in this embodiment, and the CTD has beenset to 200 cm. The position of the participant 401 has been determinedby the Position Processor 202, and the Gain Weight Processor 203 hasdetermined the distance 402 to be 135 cm in this embodiment. Thispositions the participant 401 within the CTD 108. Based on thecalculations described above, the calculated Gain Value used in thisembodiment to set the Channel Processor AGC 201 to is 2.3. Preferably,only some of the microphones 403 are enabled, n=5, and the permicrophone α gain value is 0.444. One Microphone is partially turned onwith a fractional value of f=0.265. The microphone(s) 403 selected arebased on the closest proximity to the participant 401.

FIG. 5 illustrates the microphone arrangement 503 and gain weight valuesα when a participant 501 is located inside of the MTD 109. The Figureshows the circuit comprising the microphone arrangement 503, Gain weightmultipliers 205, and the Summer 206. The MTD 109 has been set to 57.7 cmand the CTD has been set to 200 cm. The position of the participant 501has been determined by the Position Processor 202, and the Gain WeightProcessor 203 has determined the distance 502 to be 24 cm in thisembodiment. This positions the participant 501 within the CTD 108. Asthis distance may be too close for the system to control the gain, amicrophone further from the source (e.g., 62 cm) is selected to be theprimary on microphone. Based on the calculations described earlier, thecalculated Gain Value required to set the Channel Processor AGC 201 tois 1.07 in this embodiment. Only some of the microphones 503 areenabled, n=1, and the per microphone a gain value is 0.997. Onemicrophone is partially turned on with a fractional value of f=0.077.The microphone(s) 503 are selected based on determining the microphones503 that are located outside of a distance equal to the MTD 109. In thisembodiment, the microphone(s) 503 selected are 62 cm away from theparticipant, which is a distance greater than the MTD 109 of 57.7 cm.

FIG. 6 a illustrates a flow chart outlining the logic to derive theprocessing gain to identify the position of the sound source 107. Thepurpose of the system is to create an improved sound output signal 615by combining the inputs from the individual microphone elements in thearray in a way that increases the magnitude of the direct sound 610received at the microphone array relative to the reverb and noisecomponents. If the magnitude of the direct signal 610 is doubledrelative to the reverb and noise signals, it will have roughly the sameeffect as halving the distance between the microphones 112 and the soundsource 107. The signal strength when the array is focused on a soundsource 107 divided by the signal strength when the array is not focusedon any sound source 107 (such as ambient background noise, for example)is defined as the processing gain of the system. The system preferablysets up thousands of listening positions within the room andsimultaneously measures the processing gain at each of these locations.The virtual listening position with the largest processing gain issubstantially the location of the sound source 107. Of course, theprocessing of these flowcharts may be performed in any of the devices,servers, computers, FPGAs, DSPs, and/or ASICs described above.

To derive the processing gains 608, the volume of the room where soundpickup is desired is preferably divided into a large number of virtualmicrophone positions. When the array is focused on a given virtualmicrophone, then any sound source within a close proximity of thatlocation will produce an increased processing gain at that virtualmicrophone. The volume around each virtual microphone in which a soundsource will produce maximum processing gain at that point, may bedefined as a bubble. Based on the location of each microphone and thedefined 3D location for each virtual microphone, and using the speed ofsound which can be calculated given the current measured roomtemperature, the system can determine the expected propagation delayfrom each virtual microphone to each microphone array element 112.

The flow chart in FIG. 6 b illustrates the signal flow within theprocessing unit. This example monitors 8192 bubbles simultaneously. Thesound from each microphone element 112 is sampled at the same time asthe other elements within the microphone array 111 and at a fixed rateof 12 kHz. Each sample is preferably passed to a microphone elementprocessor 601. The microphone element processor 601 preferablyconditions and aligns the signals in time and weights the amplitude ofeach sample so they can be passed on to the summing node 604.

The signal components 620 from the microphones element processors 601are preferably summed at node 604 to provide the combined microphonearray signal for each of the 8192 bubbles. Each bubble signal ispreferably converted into a power signal at node 605 by squaring thesignal samples. The power signals are then summed over a given timewindow by the 8192 accumulators at node 607. The sums represent thesignal energy over that time period. The processing gain for each bubbleis preferably calculated at node 608 by dividing the energy of eachbubble by the energy of an ideal unfocused signal 622. The unfocusedsignal energy is preferably calculated by summing at 619 the energies ofthe signals from each microphone element 618 over the given time window,weighted by the maximum ratio combining weight squared. This is theenergy that would be expected if all of the signals were uncorrelated.The processing gain 608 is preferably calculated for each bubble bydividing the microphone array signal energy by the unfocused signalenergy 622.

Processing Gain is achieved because signals from a common sound sourceall experience the same delay before being combined which results inthose signals being added up coherently, meaning that their amplitudesadd up. If 12 equal amplitude and time aligned direct signals 601 arecombined the resulting signal will have an amplitude 12× higher, or apower level 144× higher. Signals from different sources and signals fromthe same source with significantly different delays, as the signals fromreverb and noise do not add up coherently and do not experience the samegain.

In the extremes, the signals are completely uncorrelated and will add uporthogonally. If 12 equal amplitude orthogonal signals are added up, thesignal will have roughly 12× the power of the original signal or a 3.4×increase in amplitude (measured as rms). The difference between the 12×gain of the direct signal 601 and the 3.4× gain of the reverb and noisesignals is the net processing gain (3.4 or 11 dB) of the microphonearray when it is focused on the sound source 107. This makes the signalsound as if you have moved the microphone 608 3.4× closer to the soundsource. This example uses a 12 microphone array but it could be extendedto an arbitrary number (N) resulting in a maximum possible processinggain of sqrt(N) or 10 log (N) dB.

The bubble processor system preferably simultaneously focuses themicrophone array 111 on 8192 points in 3-D space using the methoddescribed above. The energy level of a short burst of sound signal(50-100 ms) is measured at each of the 8192 virtual microphone bubblepoints and compared to the energy level that would be expected if thesignals combined orthogonally. This gives the processing gain 608 ateach point. The virtual microphone bubble that is closest to the soundsource should experience the highest processing gain and be representedas a peak in the output. Once determined, the location is known.

Node 606 searches through the output of the processing gain unit 608 forthe bubble with the highest processing gain. The (x,y,z) location 301120of the virtual microphone corresponding to that bubble can then bedetermined by looking up the index in the original configuration todetermine the exact location of the sound source. The parameters 614maybe communicated to various electronic devices to steer and focus themto the identified sound source position.

After deriving the location of the sound source, focusing the microphonearray on that sound source can be accomplished after achieving the gain.The bubble processor is preferably designed to find the sound sourcequickly enough so that the microphone array can be focused while thesound source is active, which can be a very short window of opportunity.The bubble processor system is preferably able to find new sound sourcesin less than 100 ms. Once found, the microphone array focuses on thatlocation to pick up the sound source signal and the system reports thelocation of the sound through the Identify Source Signal Position 306 toother internal processes and to the host computer, so that it canimplement sound sourced location based applications.

The embodiments described in this application have been presented withrespect to use in one or more conference rooms preferably with multiusers. However, the present invention may also find applicability inother environments such as: 1. Commercial transit passenger and crewcabins such as, but not limited to, aircraft, busses, trains and boats.All of these commercial applications can be outfitted with microphonesand can benefit from consist desired source volume and control of theambient sound conditions which can vary from moderate to considerable;2. Private transportation such as cars, truck, and mini vans, wherecommand and control applications and voice communication applicationsare becoming more prominent; 3. Industrial applications such asmanufacturing floors, warehouses, hospitals, and retail outlets to allowfor audio monitoring and to facilitate employee communications withouthaving to use specific portable devices; and 4. Drive through windowsand similar applications, where ambient sounds levels can be quite highand variable, can be controlled to consistent levels within the scope ofthe invention. Also, the processing described above may be carried outin one or more devices, one or more servers, cloud servers, etc.

The individual components shown in outline or designated by blocks inthe attached Drawings are all well-known in the electronic processingarts, and their specific construction and operation are not critical tothe operation or best mode for carrying out the invention.

While the present invention has been described with respect to what ispresently considered to be the preferred embodiments, it is to beunderstood that the invention is not limited to the disclosedembodiments. To the contrary, the invention is intended to cover variousmodifications and equivalent arrangements included within the spirit andscope of the appended claims. The scope of the following claims is to beaccorded the broadest interpretation so as to encompass all suchmodifications and equivalent structures and functions.

What is claimed is:
 1. A method of controlling one or more microphonesin a plurality of microphones, based on measured distance informationfrom a sound source to each of the plurality of microphones, in a sharedphysical space having the plurality of microphones and the sound source,comprising: receiving from the plurality of microphones, sound signalscorresponding to the measured distance information; determining, usingone or more processors, position information corresponding to the soundsource in the shared space; determining, using the one or moreprocessors, the measured distance information to the sound source fromeach of the plurality of the microphones in the shared space, based onthe position information; controlling, using the one or more processors,one or more microphones of the plurality of microphones, based on themeasured distance information; selecting and enabling one or moremicrophones of the plurality of microphones, using the one or moreprocessors, based on zones defined by the measured distance informationof the sound source from the one or more microphones of the plurality ofmicrophones such that: (i) when the sound source is outside of aconfigurable threshold distance, all microphones of the plurality ofmicrophones are enabled; (ii) when the sound source is between theconfigurable threshold distance and a minimum threshold distance, selectat least two microphones of the plurality of microphones, and enablethem differently depending on their individual distances from the soundsource; and (iii) when the sound source is within the minimum thresholddistance, select at least two microphones of the plurality ofmicrophones, and enable them such that at least one of these will beenabled as fractionally on.
 2. The method according to claim 1, whereinthe plurality of microphones are disposed in a 2D array in the sharedphysical space.
 3. The method according to claim 1, wherein theplurality of microphones are disposed in a 3D array in the sharedphysical space.
 4. The method according to claim 1, wherein the one ormore processors comprise at least one weight gain processor.
 5. Themethod according to claim 1, wherein the one or more processors compriseat least one position processor.
 6. The method according to claim 5,wherein the one or more processors comprise at least one channelprocessor.
 7. The method according to claim 6, wherein the at least onechannel processor calculates delays in the microphones using positionalinformation from the at least one position processor.
 8. The methodaccording to claim 7, wherein the at least one channel processorcomprises, for each channel, a channel multiplier and a channel delay.9. The method according to claim 8, wherein the at least one positionprocessor determines a coordinate (x,y,z) location of the sound sourceby a highest processing gain.
 10. The method according to claim 1,wherein the one or more processors determine position informationcorresponding to plural sound sources in the shared space.
 11. A programcode embodied in at least one non-transitory computer readable mediumfor controlling one or more microphones in a plurality of microphones,based on measured distance information from a sound source to each ofthe plurality of microphones, in a shared physical space having theplurality of microphones and the sound source, said program comprisinginstructions causing at least one processor to: receive from theplurality of microphones, sound signals corresponding to the measured distance information; determine, using one or more processors, positioninformation corresponding to the sound source in the shared space;determine, using the one or more processors, the measured distanceinformation to the sound source from each of the plurality of themicrophones in the shared space, based on the position information;control, using the one or more processors, one or more microphones ofthe plurality of microphones, based on the measured distanceinformation; select and enable one or more microphones of the pluralityof microphones, using the one or more processors, based on zones definedby the measured distance information of the sound source from the one ormore microphones of the plurality of microphones such that: (i) when thesound source is outside of a configurable threshold distance, allmicrophones of the plurality of microphones are enabled; (ii) when thesound source is between the configurable threshold distance and aminimum threshold distance, select at least two microphones of theplurality of microphones, and enable them differently depending on theirindividual distances from the sound source; and (iii) when the soundsource is within the minimum threshold distance, select at least twomicrophones of the plurality of microphones, and enable them such thatat least one of these will be enabled as fractionally on.
 12. Theprogram code according to claim 11, wherein the plurality of microphonesare disposed in a 2D array in the shared physical space.
 13. The programcode according to claim 11, wherein the plurality of microphones aredisposed in a 3D array in the shared physical space.
 14. The programcode according to claim 11, wherein the one or more processors compriseat least one weight gain processor.
 15. The program code according toclaim 11, wherein the one or more processors comprise at least oneposition processor.
 16. The program code according to claim 15, whereinthe one or more processors comprise at least one channel processor. 17.The program code according to claim 16, wherein the at least one channelprocessor calculates delays in the microphones using positionalinformation from the at least one position processor.
 18. The programcode according to claim 17, wherein the at least one channel processorcomprises, for each channel, a channel multiplier and a channel delay.19. The program code according to claim 18, wherein said program codecomprises instructions causing the at least one position processor todetermine a coordinate (x,y,z) location of the sound source by a highestprocessing gain.
 20. The program code according to claim 11, whereinsaid program code comprises instructions causing the one or moreprocessors to determine position information corresponding to pluralsound sources in the shared space.
 21. An apparatus for controlling oneor more microphones in a plurality of microphones, based on measureddistance information from a sound source to each of the plurality ofmicrophones, in a shared physical space having the plurality ofmicrophones and the sound source, comprising one or more processors thatare configured to: receive from the plurality of microphones, soundsignals corresponding to the measured distance information; determine,using one or more processors, position information corresponding to thesound source in the shared space; determine, using the one or moreprocessors, the measured distance information to the sound source fromeach of the plurality of the microphones in the shared space, based onthe position information; control, using the one or more processors, oneor more microphones of the plurality of microphones, based on themeasured distance information; select and enable one or more microphonesof the plurality of microphones, using the one or more processors, basedon zones defined by the measured distance information of the soundsource from the one or more microphones of the plurality of microphonessuch that: (i) when the sound source is outside of a configurablethreshold distance, all microphones of the plurality of microphones areenabled; (ii) when the sound source is between the configurablethreshold distance and a minimum threshold distance, select at least twomicrophones of the plurality of microphones, and enable them differentlydepending on their individual distances from the sound source; and (iii)when the sound source is within the minimum threshold distance, selectat least two microphones of the plurality of microphones, and enablethem such that at least one of these will be enabled as fractionally on.22. The apparatus according to claim 21, wherein the plurality ofmicrophones are disposed in a 2D array in the shared physical space. 23.The apparatus according to claim 21, wherein the plurality ofmicrophones are disposed in a 3D array in the shared physical space. 24.The apparatus according to claim 21, wherein the one or more processorscomprise at least one weight gain processor.
 25. The apparatus accordingto claim 21, wherein the one or more processors comprise at least oneposition processor.
 26. The apparatus according to claim 25, wherein theone or more processors comprise at least one channel processor.
 27. Theapparatus according to claim 26, wherein the at least one channelprocessor calculates delays in the microphones using positionalinformation from the at least one position processor.
 28. The apparatusaccording to claim 27, wherein the at least one channel processorcomprises, for each channel, a channel multiplier and a channel delay.29. The apparatus according to claim 28, wherein the at least oneposition processor determines a coordinate (x,y,z) location of the soundsource by a highest processing gain.
 30. The apparatus according toclaim 21, wherein the one or more processors determine positioninformation corresponding to plural sound sources in the shared space.